Duplex Scorpion primers in SNP analysis and FRET applications

Scorpions are fluorogenic PCR primers with a probe element attached at the 5′-end via a PCR stopper. They are used in real-time amplicon-specific detection of PCR products in homogeneous solution. Two different formats are possible, the ‘stem–loop’ format and the ‘duplex’ format. In both cases the probing mechanism is intramolecular. We have shown that duplex Scorpions are efficient probes in real-time PCR. They give a greater fluorescent signal than stem–loop Scorpions due to the vastly increased separation between fluorophore and quencher in the active form. We have demonstrated their use in allelic discrimination at the W1282X locus of the ABCC7 gene and shown that they can be used in assays where fluorescence resonance energy transfer is required.     

Self-assembly of Pseudomonas fluorescens lipase into bimolecular aggregates dramatically affects functional properties

It has been found that lipase from Pseudomonas fluorescens (PFL) is able to aggregate into bimolecular structures (MW around 66 kD) even at moderate enzyme concentrations. At very low enzyme concentrations and in the presence of detergents, the same enzyme displayed a unimolecular structure with a molecular weight of 33 kD. Both enzyme structures displayed different functional properties. First, the bimolecular structure was much more stable than the unimolecular species (the bimolecular structure maintained over 80% of initial activity after 72 hours at 45 degrees C, while the unimolecular structure retained only around 30% of initial activity after 4 hours of incubation under the same experimental conditions); and the bimolecular form presented a higher optimal T. Second, the unimolecular form showed a much lower K(M) for ethyl butyrate than the bimolecular form. Third, the interfacial activation in biphasic substrate-aqueous milieu was higher for the bimolecular form. Fourth, the unimolecular structure was less active but much more enantioselective than the unimolecular species in the model reaction used. It is proposed that the bimolecular aggregates of PFL might be formed by two open lipase molecules (mutual interfacial activation), in intimate contact, and that the bimolecular form represents an example of "pseudo-quaternary" structure.     

The Renaturation of Denatured DNA

The kinetics of renaturation of heat-denatured DNA from E. coli and pneumococcus have been examined by ultraviolet absorption measurements. The molecularity of the reaction was assessed by three independent treatments of the data, and all lead to the conclusion that renaturation is essentially first order at 60°; at 70° and 80° there is an increasing second order component, resulting in simultaneous unimolecular and bimolecular kinetics. The unimolecular kinetics rule out reaction between two, kinetically separate strands, indicating rather the zippering-up of a single, denatured entity. The bimolecular kinetics can be attributed to the complexing of two such entities; thus, the genetic or density-labeled complexes that have been observed by other investigators can be accounted for without invoking strand separation. Since renaturation at best is never complete, the free ends of two renatured molecules permit sufficient bimolecular reaction to produce density hybrids. The observed kinetics can be accounted for if the hydrogen bonds of DNA are broken during heat denaturation but the strands do not separate. Light scattering supports this by showing that the molecular weight is unchanged by denaturation. Since there is no existing evidence that is inconsistent with this hypothesis, it is reasonable to conclude that heat denaturation does not completely separate the entangled strands of the DNA molecule.     

Kinetic study of lipoxygenase-hydroperoxylinoleic acid interaction.

Interaction of lipoxygenase with hydroperoxylinoleic acid, which is the product of this enzyme reaction and acts as an activator, was studied kinetically by the fluorescence stopped-flow method. The kinetic features are consistent with a two-step mechanism involving a fast bimolecular association process followed by a slow unimolecular process. The dissociation constant of the bimolecular process was 3 (+/-2) - 10(-5) M, which was appreciably dependent on temperature and pH, in contrast to the rate constant of the latter process. The enthalpy and the entropy of activation for the unimolecular process were estimated to be 21 kcal/mol and 20 e.u., respectively. The pH dependence of the rate constant indicated that an ionizable group with pK of about 8.6 is involved in the interaction. Linoleic acid, the substrate of lipoxygenase, and oleic acid inhibited the interaction between the lipoxygenase and the hydroperoxylinoleic acid by reducing the rate. A series of saturated monohydric alcohols also reduced the rate of the interaction as the chain length of the alcohols increases, though methanol and ethanol increased the rate of the interaction.     

Temperature dependence of anion transport inhibitor binding to human red cell membranes

The binding characteristics of the inhibitor of anion transport in human red cells, 4,4'-dibenzamido-2,2'-disulfonic stilbene (DBDS), to the anion transport protein of red cell ghost membranes in buffer containing 150 mM NaCl have been measured over the temperature range 0-30 degrees C by equilibrium and stopped-flow fluorescence methods. The equilibrium dissociation constant Keq, increased with temperature. No evidence of a 'break' in the ln(Keq) vs. 1/T plot was found. The standard dissociation enthalpy and entropy changes calculated from the temperature dependence are 9.1 +/- 0.9 kcal/mol and 3.2 +/- 0.3 e.u., respectively. Stopped-flow kinetic studies resolve the overall binding into two steps: a bimolecular association of DBDS with the anion transport protein, followed by a unimolecular rearrangement of the DBDS-protein complex. The rate constants for the individual steps in the binding mechanism can be determined from an analysis of the concentration dependence of the binding time course. Arrhenius plots of the rate constants showed no evidence of a break. Activation energies for the individual steps in the binding mechanism are 11.6 +/- 0.9 kcal/mol (bimolecular, forward step), 17 +/- 2 kcal/mol (bimolecular, reverse step), 6.4 +/- 2.3 kcal/mol (unimolecular, forward step), and 10.6 +/- 1.9 kcal/mol (unimolecular, reverse step). Our results indicate that there is an appreciable enthalpic energy barrier for the bimolecular association of DBDS with the transport protein, and appreciable enthalpic and entropic barriers for the unimolecular rearrangement of the DBDS-protein complex.     

Locked nucleic acids for optimizing displacement probes for quantitative real-time PCR

Displacement probes have recently been described as a novel probe-based detection system for use in both quantitative real-time polymerase chain reaction (PCR) and single nucleotide polymorphism genotyping analysis. Previous reports have shown that shorter probes (23 mer) had improved detection sensitivity relative to longer probes (29 mer), with the likely reason for this effect being the improved hybridization kinetics of shorter probes. Sterically modified locked nucleic acids (LNAs) have been used to improve the design of a range of real-time PCR probes by raising the melting temperature (Tm) of the probe and enabling shorter probe designs to be considered. A displacement probe for gapdh was designed and tested successfully, and this probe was then redesigned with LNAs to an 11 mer probe. This probe showed increased detection sensitivity compared with the original 26 mer probe. To detect the widest range of displacement probe designs at maximum sensitivity, we have also developed a novel fluorescence capture two-step PCR protocol. This method produces enhanced probe quenching with a single standardized protocol ideal for high-throughput applications. The displacement probes tested produced sensitive and efficient quantitative analyses of template serial dilutions when compared with a range of commercially available predesigned real-time PCR detection systems, including TaqMan MGB probes, QuantiTect MGB probes, and LUX primers.     

TaqMan—MGB荧光定量RT-PCR技术快速检测H5亚型禽流感病毒

建立以TaqMan-MGB荧光探针为特点的荧光定量RT-PCR方法,用于检测H5亚型禽流感病毒。针对H5亚型禽流感病毒血凝素(HA)基因保守区域设计特异性引物与TaqMan-MGB荧光探针,筛选并优化荧光定量RT-PCR反应体系与反应条件,用以提高方法的特异性、敏感性与准确性;并通过体外克隆技术建立病毒基因拷贝数进行定量分析。结果表明:引物与探针的优化浓度分别640nmol/L和480nmol/L,体系具有良好的保守性和特异性,与其他呼吸道病毒均无交叉反应。方法检测灵敏度为100拷贝/反应,标准曲线线性范围为107～102拷贝/反应,从病毒核酸提取至检测完成仅需3h左右,操作简便,重现性好。本研究建立的TaqMan-MGB荧光定量PCR方法特异、敏感、快速,适合于临床实验室进行H5亚型禽流感病毒的快速定量检测。     

New approach to real-time nucleic acids detection: folding polymerase chain reaction amplicons into a secondary structure to improve cleavage of F?rster resonance energy transfer probes in 5′-nuclease assays

The article describes a new technology for real-time polymerase chain reaction (PCR) detection of nucleic acids. Similar to Taqman, this new method, named Snake, utilizes the 5′-nuclease activity of Thermus aquaticus (Taq) DNA polymerase that cleaves dual-labeled Förster resonance energy transfer (FRET) probes and generates a fluorescent signal during PCR. However, the mechanism of the probe cleavage in Snake is different. In this assay, PCR amplicons fold into stem–loop secondary structures. Hybridization of FRET probes to one of these structures leads to the formation of optimal substrates for the 5′-nuclease activity of Taq. The stem–loop structures in the Snake amplicons are introduced by the unique design of one of the PCR primers, which carries a special 5′-flap sequence. It was found that at a certain length of these 5′-flap sequences the folded Snake amplicons have very little, if any, effect on PCR yield but benefit many aspects of the detection process, particularly the signal productivity. Unlike Taqman, the Snake system favors the use of short FRET probes with improved fluorescence background. The head-to-head comparison study of Snake and Taqman revealed that these two technologies have more differences than similarities with respect to their responses to changes in PCR protocol, e.g. the variations in primer concentration, annealing time, PCR asymmetry. The optimal PCR protocol for Snake has been identified. The technology’s real-time performance was compared to a number of conventional assays including Taqman, 3′-MGB-Taqman, Molecular Beacon and Scorpion primers. The test trial showed that Snake supersedes the conventional assays in the signal productivity and detection of sequence variations as small as single nucleotide polymorphisms. Due to the assay’s cost-effectiveness and simplicity of design, the technology is anticipated to quickly replace all known conventional methods currently used for real-time nucleic acid detection.     

In situ DNA amplification with magnetic primers for the electrochemical detection of food pathogens

A sensitive and selective genomagnetic assay for the electrochemical detection of food pathogens based on in situ DNA amplification with magnetic primers has been designed. The performance of the genomagnetic assay was firstly demonstrated for a DNA synthetic target by its double-hybridization with both a digoxigenin probe and a biotinylated capture probe, and further binding to streptavidin-modified magnetic beads. The DNA sandwiched target bound on the magnetic beads is then separated by using a magneto electrode based on graphite-epoxy composite. The electrochemical detection is finally achieved by an enzyme marker, anti-digoxigenin horseradish peroxidase (HRP). The novel strategy was used for the rapid and sensitive detection of polymerase chain reaction (PCR) amplified samples. Promising resultants were also achieved for the DNA amplification directly performed on magnetic beads by using a novel magnetic primer, i.e., the up PCR primer bound to magnetic beads. Moreover, the magneto DNA biosensing assay was able to detect changes at single nucleotide polymorphism (SNP) level, when stringent hybridization conditions were used. The reliability of the assay was tested for Salmonella spp., the most important pathogen affecting food safety.     

Identification of Staphylococcus epidermidis using a 16S rRNA-directed oligonucleotide probe

Staphylococcus epidermidis is the most medically significant of the coagulase-negative staphylococci. An oligonucleotide probe (pSe) for identification of S. epidermidis was defined by comparing the sequences of the 16S rRNA variable region V6 from numerous coagulase-negative staphylococci. In order to increase the sensitivity of the detection, polymerase chain reaction amplification of the variable region with primers based on the conserved flanking sequences was applied. The detection limit of the polymerase chain reaction assay combined with pSe probe was shown to be 1 fg which corresponds to about one single bacterium. Additionally, a sensitive, non-radioisotopic system with chemiluminescence detection was tested.     

Use of 9-aminoacridine as a probe in a kinetic study of DNA-poly-L-lysine interaction

An attempt has been made to use a fluorescent dye as a probe in a kinetic study of DNA-poly-L-lysine interaction by the stopped-flow method. It is found that 9-aminoacridine is suitable for this purpose. The results have indicated that polylysine binds to DNA at least in two steps; a slow unimolecular process (τ ～ 2 msec) being preceded by a rapid bimolecular one (τ ? 1 msec). The usefulness of this method for the kinetic study of the interaction between DNA and basic polypeptides has been emphasized.     

单分子荧光共振能量转移技术

单分子荧光共振能量转移技术（single molecule fluorescence resonance energy transfer,smFRET）通过检测单个分子内的荧光供体及受体间荧光能量转移的效率,来研究分子构象的变化。在单分子探测技术发展之前,大多数的分子实验是探测分子的综合平均效应（ensemble averages）,这一平均效应掩盖了许多特殊的信息。单分子探测可以对体系中的单个分子进行研究,得到某一分子特性的分布状况,也可研究生物分子的动力学反应。介绍了近来单分子荧光共振能量转移技术的进展。     

Fluctuation analysis in small chemically reacting systems

A theory of noise fluctuations is developed which is applicable to systems of any size in which unimolecular or bimolecular reactions are occurring. The main difference between small and large reacting systems is that in the former the probability of finding a particle in a particular state does not obey a Gaussian distribution, but satisfies a distribution which reflects the mechanism of the chemical reaction. This difference is reflected in the main result of the theory: an autocorrelation function that is expressible as a sum of exponentials, the amplitudes of which are explicit functions of the moments of the distribution. Thus, by using small systems, the autocorrelation function,in principle, allows the elucidation of reaction mechanisms. Numerical simulations indicate that for reacting systems having ten or fewer particles, the deviation of the autocorrelation function from a single exponential should be easily detectable, and that estimates of the first four moments of the distribution should be possible. Accurate inference of the distribution, however, will require further mathematical and experimental advances.     

PCR detection of nearly any dengue virus strain using a highly sensitive primer 'cocktail'

PCR detection of viral pathogens is extremely useful, but suffers from the challenge of detecting the many variant strains of a given virus that arise over time. Here, we report the computational derivation and initial experimental testing of a combination of 10 PCR primers to be used in a single high-sensitivity mixed PCR reaction for the detection of dengue virus. Primer sequences were computed such that their probability of mispriming with human DNA is extremely low. A 'cocktail' of 10 primers was shown experimentally to be able to detect cDNA clones representing the four serotypes and dengue virus RNA spiked into total human whole blood RNA. Computationally, the primers are predicted to detect 95% of the 1688 dengue strains analyzed (with perfect primer match). Allowing up to one mismatch and one insertion per primer, the primer set detects 99% of strains. Primer sets from three previous studies have been compared with the present set of primers and their relative sensitivity for dengue virus is discussed. These results provide the formulation and demonstration of a mixed primer PCR reagent that may enable the detection of nearly any dengue strain irrespective of serotype, in a single PCR reaction, and illustrate an approach to the broad problem of detecting highly mutable RNA viruses.     

Quantum chemical investigation of the thermal pyrolysis reactions of the carboxylic group in a brown coal model

Different reaction pathways of the carboxylic group in a brown coal model were investigated by applying density function quantum chemical theory, examining the possible cross-linking and decomposition reactions between the hydrogen bonded carboxylic group–carboxylic group and the carboxylic group–hydroxyl group during the thermal pyrolysis process. The results show that bimolecular dehydration and decarboxylation of hydrogen bonded carboxylic groups have distinctly lower activation barriers and therefore, proceed preferentially at low temperature. The esterification reaction between the hydrogen bonded carboxylic group and hydroxyl group, together with unimolecular decarboxylation of isolated single carboxylic groups were also possible at moderate temperature. Aryl–aryl coupling is thought to occur via radical pyrolysis and recombination at relatively high temperature.     

Construction and evaluation of a kinetic scheme for RecA-mediated DNA strand exchange

The Escherichia coli RecA protein is the prototype of a class of proteins playing a central role in genomic repair and recombination in all organisms. The unresolved mechanistic strategy by which RecA aligns a single strand of DNA with a duplex DNA and mediates a DNA strand switch is central to understanding its recombinational activities. Toward a molecular-level understanding of RecA-mediated DNA strand exchange, we explored its mechanism using oligonucleotide substrates and the intrinsic fluorescence of 6-methylisoxanthopterin (6MI). Steady- and presteady-state spectrofluorometric data demonstrate that the reaction proceeds via a sequential four-step mechanism comprising a rapid, bimolecular association step followed by three slower unimolecular steps. Previous authors have proposed multistep mechanisms involving two or three steps. Careful analysis of the differences among the experimental systems revealed a previously undiscovered intermediate (N1) whose formation may be crucial in the kinetic discrimination of homologous and heterologous sequences. This observation has important implications for probing the fastest events in DNA strand exchange using 6MI to further elucidate the molecular mechanisms of recombination and recombinational repair.     

A long downstream probe-based platform for multiplex target capture

A simple and rapid detection platform was established for multiplex target capture through generating single-strand long downstream probe (ssLDP), which was integrated with the ligase detection reaction (LDR) method for the purpose of multiplicity and high specificity. To increase sensitivity, the ladder-like polymerase chain reaction (PCR) amplicons were generated by using universal primers that complement ligated products. Each of the amplicons contained a stuffer sequence with a defined yet variable length. Thus, the length of the amplicon is an index of the specific suppressor, allowing its identification via electrophoresis. The multiplexed diagnostic platform was optimized using standard plasmids and validated by using potato virus suppressors as a detection model. This technique can detect down to 1.2 × 10³ copies for single or two mixed target plasmids. When compared with microarray results, the electrophoresis showed 98.73–100% concordance rates for the seven suppressors in the 79 field samples. This strategy could be applied to detect a large number of targets in field and clinical surveillance.     

转基因玉米2A-5特异性PCR方法的建立

根据转基因玉米2A-5的旁侧序列信息,设计并筛选出最佳特异性引物及Taqman探针组合2A-5-5-QF8、2A-5-5-QR8、2A-5-5-QP8,优化了该引物探针组合的反应体系,建立了转基因玉米2A-5转化体特异性PCR检测方法。将特异性引物及Taqman探针组合用于qRT-PCR和ddPCR技术,研究了转基因玉米2A-5转化体的定量检测方法,发现PCR定量检测转基因含量与测定样品转基因含量之间呈高度正相关。研究获得的转基因玉米2A-5转化体特异性PCR检测方法及定量qRT-PCR、ddPCR检测方法具有较高的特异性、准确性和灵敏度,是今后准确、高效检测2A-5及其产品的有效方法之一,同时也为我国转基因生物安全监管提供了良好的技术支撑。     

A two-layer ONIOM study of thiophene cracking catalyzed by proton- and cation-exchanged FAU zeolite

A two-layer ONIOM study on the hydrodesulfurization mechanism of thiophene in H-FAU and M-FAU (M?=?Li⁺, Na⁺, and K⁺) has been carried out. The calculated results reveal that in H-FAU, for a unimolecular mechanism, the rate-determining step is hydrogenation of alkoxide intermediate. The assistance of H₂O and H₂S molecules does not reduce the difficulty of the C-S bond cracking step more effectively. A bimolecular hydrodesulfurization mechanism is more favorable due to the lower activation barriers. The rate-determining step is the formation of 2-methylthiophene, not the C-S bond cracking of thiophene. Moreover, the ring opening of thiophene is much easier to occur than the desulfurization step. A careful analysis of energetics indicates that H₂S, propene, and methyl thiophene are the major products for the hydrodesulfurization process of thiophene over H-FAU zeolite, in good agreement with experimental findings. In M-FAU zeolites, both unimolecular and bimolecular cracking processes are difficult to occur because of the high energy barriers. Compared to the case on H-FAU, the metal cations on M-FAU increase the difficulty of occurrence of bimolecular polymerization and subsequent C-S bond cracking steps.

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Graphical abstract Hydrodesulfurization process of thiophene can take place in H-FAU zeolite. Two different mechanisms, unimolecular and bimolecular ones, have been proposed and evaluated in detail. The bimolecular mechanism is more favorable due to lower activation barrier as described in the picture above. Our calculated data indicate that H₂S, propene, and methylthiophene are the major products, in good agreement with experimental observations. The effect of metal cations on the reaction mechanism is also investigated in this work.

     

Direct comparison of levels of genetic variation in tomato detected by a GACA-containing microsatellite probe and by random amplified polymorphic DNA.

In this study, a direct comparison was made of the ability of four selected random amplified polymorphic DNA (RAPD) primers and a GACA-containing microsatellite probe to detect genetic variation in Lycopersicon. Of the 89 RAPD primers initially tested, 85 showed differences between a representative of Lycopersicon pennellii and L. esculentum, but only 4 distinguished among three L. esculentum cultivars. These four primers were subsequently tested on representatives of six Lycopersicon species. In pairwise comparisons of species, all or 14 of the 15 combinations could be distinguished by single primers. When the primers were tested on 15 L. esculentum cultivars, 90 of the 105 combinations could be distinguished by the four primers together. Finally, none of 118 tested primers showed reproducible differences among calli or progeny of régénérants from tissue culture, although some of the plants had inherited morphological mutations. The probe pWVA16, which detects GACA-containing microsatellites, could distinguish in TaqI-digested DNA the representatives of Lycopersicon species as well as all the L. esculentum cultivars tested. The probe was unable to detect polymorphisms among calli and the progeny of regenerants from tissue culture. An analysis of the results showed that the four selected RAPD primers were able to detect polymorphic bands among species at a frequency of 80%, and among cultivars at a frequency of 44%. In contrast, the microsatellite probe detected polymorphic bands at a frequency of 100 and 95%, respectively. The GACA-containing probe did not detect any common bands among the representatives of the six species, while band sharing with RAPDs was 48%. These results indicate that the two methods detect two types of DNA that differ in their degree of variability.